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Stefan cel Mare
University of Suceava
Faculty of Electrical Engineering and
Computer Science
13, Universitatii Street
Suceava - 720229
ROMANIA

Print ISSN: 1582-7445
Online ISSN: 1844-7600
WorldCat: 643243560
doi: 10.4316/AECE


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  4/2022 - 7

Performance Analysis of Single Loop Current Controller at Grid Side Inverter Regarding LCL Filter Parameters and System Delay

STOJANOVIC, L. See more information about STOJANOVIC, L. on SCOPUS See more information about STOJANOVIC, L. on IEEExplore See more information about STOJANOVIC, L. on Web of Science, BAKIC, F. See more information about  BAKIC, F. on SCOPUS See more information about  BAKIC, F. on SCOPUS See more information about BAKIC, F. on Web of Science, MILIC, A. See more information about MILIC, A. on SCOPUS See more information about MILIC, A. on SCOPUS See more information about MILIC, A. on Web of Science
 
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Download PDF pdficon (2,997 KB) | Citation | Downloads: 574 | Views: 128

Author keywords
current control, digital control, filtering, microgrids, system analysis and design

References keywords
grid(13), damping(9), control(9), power(8), connected(8), active(8), phase(6), inverters(5), filters(5), filter(5)
Blue keywords are present in both the references section and the paper title.

About this article
Date of Publication: 2022-11-30
Volume 22, Issue 4, Year 2022, On page(s): 55 - 64
ISSN: 1582-7445, e-ISSN: 1844-7600
Digital Object Identifier: 10.4316/AECE.2022.04007
Web of Science Accession Number: 000920289700007
SCOPUS ID: 85150293998

Abstract
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In the grid-connected systems, LCL filters are widely used for eliminating the generated switching current ripples due to better attenuation in comparison with L or LC filter. However it is known that stability of digital controlled LCL filter can present a challenge due to induced delay. This paper presents conditions of system stability in dependence of filter characteristics such as resonant frequency, inductors and capacitor parameter variations. Stability analysis and system performance are observed and compared. Derived results are tested and confirmed on Hardware-in-the-loop HIL402 device. Obtained results are discussed and suggestions are provided in terms of the practical implementation of the control system.


References | Cited By  «-- Click to see who has cited this paper

[1] M. Liserre, F. Blaabjerg, and S. Hansen, "Design and control of an LCL-filter-based three-phase active rectifier," IEEE Trans. on Ind. Applicat., vol. 41, no. 5, pp. 1281-1291, Sep. 2005.
[CrossRef] [Web of Science Times Cited 1605] [SCOPUS Times Cited 2080]


[2] Z. Xin, X. Wang, P. C. Loh, and F. Blaabjerg, "Grid-current-feedback control for LCL-filtered grid converters with enhanced stability," IEEE Trans. Power Electron., vol. 32, no. 4, pp. 3216-3228, Apr. 2017.
[CrossRef] [Web of Science Times Cited 139] [SCOPUS Times Cited 166]


[3] J. Wang, J. D. Yan, L. Jiang, and J. Zou, "Delay-dependent stability of single-loop controlled grid-connected inverters with LCL filters," IEEE Trans. Power Electron., vol. 31, no. 1, pp. 743-757, Jan. 2016.
[CrossRef] [Web of Science Times Cited 279] [SCOPUS Times Cited 357]


[4] B. Hoseinzadeh, C. L. Bak, and F. Blaabjerg, "Impact of grid impedance variations on harmonic emission of grid-connected inverters," in 2017 IEEE Manchester PowerTech, Manchester, United Kingdom, Jun. 2017, pp. 1-5.
[CrossRef] [SCOPUS Times Cited 10]


[5] S. N. Vukosavic, L. S. Peric, and E. Levi, "A three-phase digital current controller with improved performance indices," IEEE Trans. Energy Convers., vol. 32, no. 1, pp. 184-193, Mar. 2017.
[CrossRef] [Web of Science Times Cited 19] [SCOPUS Times Cited 19]


[6] T. C. Y. Wang, Zhihong Ye, Gautam Sinha, and Xiaoming Yuan, "Output filter design for a grid-interconnected three-phase inverter," in IEEE 34th Annual Conference on Power Electronics Specialist, 2003. PESC '03, Acapulco, Mexico, 2003, vol. 2, pp. 779-784.
[CrossRef]


[7] R. Pena-Alzola, M. Liserre, F. Blaabjerg, R. Sebastian, J. Dannehl, and F. W. Fuchs, "Analysis of the passive damping losses in LCL-filter-based grid converters," IEEE Trans. Power Electron., vol. 28, no. 6, pp. 2642-2646, Jun. 2013.
[CrossRef] [Web of Science Times Cited 454] [SCOPUS Times Cited 548]


[8] H. Xiao, X. Qu, S. Xie, and J. Xu, "Synthesis of active damping for grid-connected inverters with an LCL filter," in 2012 IEEE Energy Conversion Congress and Exposition (ECCE), Raleigh, NC, USA, Sep. 2012, pp. 550-556.
[CrossRef] [SCOPUS Times Cited 16]


[9] X. Wang, F. Blaabjerg, and P. C. Loh, "Virtual RC damping of LCL-filtered voltage source converters with extended selective harmonic compensation," IEEE Trans. Power Electron., vol. 30, no. 9, pp. 4726-4737, Sep. 2015.
[CrossRef] [Web of Science Times Cited 218] [SCOPUS Times Cited 260]


[10] D. Pan, X. Ruan, C. Bao, W. Li, and X. Wang, "Capacitor-current-feedback active damping with reduced computation delay for improving robustness of LCL-type grid-connected inverter," IEEE Trans. Power Electron., vol. 29, no. 7, pp. 3414-3427, Jul. 2014.
[CrossRef] [Web of Science Times Cited 570] [SCOPUS Times Cited 682]


[11] R. Pena-Alzola, M. Liserre, F. Blaabjerg, R. Sebastian, J. Dannehl, and F. W. Fuchs, "Systematic design of the lead-lag network method for active damping in LCL-filter based three phase converters," IEEE Trans. Ind. Inf., vol. 10, no. 1, pp. 43-52, Feb. 2014.
[CrossRef] [Web of Science Times Cited 196] [SCOPUS Times Cited 239]


[12] J. Dannehl, F. W. Fuchs, S. Hansen, and P. B. Thøgersen, "Investigation of active damping approaches for PI-based current control of grid-connected pulse width modulation converters with LCL filters," IEEE Trans. on Ind. Applicat., vol. 46, no. 4, pp. 1509-1517, Jul. 2010.
[CrossRef] [Web of Science Times Cited 461] [SCOPUS Times Cited 541]


[13] W. Yao, Y. Yang, X. Zhang, F. Blaabjerg, and P. C. Loh, "Design and analysis of robust active damping for LCL filters using digital notch filters," IEEE Trans. Power Electron., vol. 32, no. 3, pp. 2360-2375, Mar. 2017.
[CrossRef] [Web of Science Times Cited 216] [SCOPUS Times Cited 269]


[14] S. G. Parker, B. P. McGrath, and D. G. Holmes, "Regions of active damping control for LCL filters," IEEE Trans. on Ind. Applicat., vol. 50, no. 1, pp. 424-432, Jan. 2014.
[CrossRef] [Web of Science Times Cited 488] [SCOPUS Times Cited 578]


[15] Y. He, H. S.-H. Chung, C. N.-M. Ho, and W. Wu, "Use of boundary control with second-order switching surface to reduce the system order for deadbeat controller in grid-connected inverter," IEEE Trans. Power Electron., vol. 31, no. 3, pp. 2638-2653, Mar. 2016.
[CrossRef] [Web of Science Times Cited 51] [SCOPUS Times Cited 61]


[16] M. Chhabra and F. Barnes, "Robust current controller design using mu-synthesis for grid-connected three phase inverter," in 2014 IEEE 40th Photovoltaic Specialist Conference (PVSC), Denver, CO, USA, Jun. 2014, pp. 1413-1418.
[CrossRef] [SCOPUS Times Cited 11]


[17] W. Jin, Y. Li, G. Sun, and L. Bu, "H repetitive control based on active damping with reduced computation delay for LCL-type grid-connected inverters," Energies, vol. 10, no. 5, p. 586, Apr. 2017.
[CrossRef] [Web of Science Times Cited 23] [SCOPUS Times Cited 24]


[18] J. M. E. Valenca and C. J. Harris, "A nyquist type criterion for the stability of multivariable linear systems," in 1978 IEEE Conference on Decision and Control including the 17th Symposium on Adaptive Processes, San Diego, CA, USA, Jan. 1978, pp. 821-823.
[CrossRef]


[19] A. Emami-Naeini and R. L. Kosut, "The generalized Nyquist criterion and robustness margins with applications," in 2012 IEEE 51st IEEE Conference on Decision and Control (CDC), Maui, HI, USA, Dec. 2012, pp. 226-231.
[CrossRef] [SCOPUS Times Cited 24]


[20] R. Guzman, L. G. de Vicuna, M. Castilla, J. Miret, and J. de la Hoz, "Variable structure control for three-phase LCL-filtered inverters using a reduced converter model," IEEE Trans. Ind. Electron., vol. 65, no. 1, pp. 5-15, Jan. 2018.
[CrossRef] [Web of Science Times Cited 57] [SCOPUS Times Cited 71]






References Weight

Web of Science® Citations for all references: 4,776 TCR
SCOPUS® Citations for all references: 5,956 TCR

Web of Science® Average Citations per reference: 217 ACR
SCOPUS® Average Citations per reference: 271 ACR

TCR = Total Citations for References / ACR = Average Citations per Reference

We introduced in 2010 - for the first time in scientific publishing, the term "References Weight", as a quantitative indication of the quality ... Read more

Citations for references updated on 2024-07-19 09:32 in 135 seconds.




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